S4-alpha mRNA translation regulation complex. II. Secondary structures of the RNA regulatory site in the presence and absence of S4

The secondary structure of the Escherichia coli alpha mRNA leader sequence has been determined using nucleases specific for single- or double-stranded RNA. Three different length alpha RNA fragments were studied at 0 degrees C and 37 degrees C. A very stable eight base-pair helix forms upstream from the ribosome initiation site, defining a 29 base loop. There is evidence for base-pairing between nucleotides within this loop and for a "pseudo-knot" interaction of some loop bases with nucleotides just 3' to the initiation codon, forming a region of complex structure. A weak helix also pairs sequences near the 5' terminus of the alpha mRNA with bases near the Shine-Dalgarno sequence. Affinity constants for the translational repressor S4 binding different length alpha mRNA fragments indicate that most of the S4 recognition features must be contained within the main helix and hairpin regions. Binding of S4 to the alpha mRNA alters the structure of the 29 base hairpin region, and probably melts the weak pairing between the 5' and 3' termini of the leader. The pseudo-knot structure and the conformational changes associated with it provide a link between the structures of the S4 binding site and the ribosome binding site. The alpha mRNA may therefore play an active role in mediating translational repression.     

Four codons in the cat-86 leader define a chloramphenicol-sensitive ribosome stall sequence.

Genes encoding chloramphenicol acetyltransferase in gram-positive bacteria are induced by chloramphenicol. Induction reflects an ability of the drug to stall a ribosome at a specific site in cat leader mRNA. Ribosome stalling at this site alters downstream RNA secondary structure, thereby unmasking the ribosome-binding site for the cat coding sequence. Here, we show that ribosome stalling in the cat-86 leader is a function of leader codons 2 through 5 and that stalling requires these codons to be presented in the correct reading frame. Codons 2 through 5 specify Val-Lys-Thr-Asp. Insertion of a second copy of the stall sequence 5' to the authentic stall sequence diminished cat-86 induction fivefold. Thus, the stall sequence can function in ribosome stalling when the stall sequence is displaced from the downstream RNA secondary structure. We suggest that the stall sequence may function in cat induction at two levels. First, the tetrapeptide specified by the stall sequence likely plays an active role in the induction strategy, on the basis of previously reported genetic suppression studies (W. W. Mulbry, N. P. Ambulos, Jr., and P.S. Lovett, J. Bacteriol. 171:5322-5324, 1989). Second, we show that embedded within the stall sequence of cat leaders is a region which is complementary to a sequence internal in 16S rRNA of Bacillus subtilis. This complementarity may guide a ribosome to the proper position on leader mRNA or potentiate the stalling event, or both. The region of complementarity is absent from Escherichia coli 16S rRNA, and cat genes induce poorly, or not at all, in E. coli.     

Site in the cat-86 regulatory leader that permits amicetin to induce expression of the gene.

Expression of the plasmid gene cat-86 is induced in Bacillus subtilis by two antibiotics, chloramphenicol and the nucleoside antibiotic amicetin. We proposed that induction by either drug causes the destabilization of a stem-loop structure in cat-86 mRNA that sequesters the ribosome-binding site for the cat coding sequence. The destabilization event frees the ribosome-binding site, permitting the initiation of translation of cat-86 mRNA. cat-86 induction is due to the stalling of a ribosome in a leader region of cat-86 mRNA, which is located 5' to the RNA stem-loop structure. A stalled ribosome that is active in cat-86 induction has its aminoacyl site occupied by leader codon 6. To test the hypothesis that a leader site 5' to codon 6 permits a ribosome to stall in the presence of an inducing antibiotic, we inserted an extra codon between leader codons 5 and 6. This insertion blocked induction, which was then restored by the deletion of leader codon 6. Thus, induction seems to require the maintenance of a precise spatial relationship between an upstream leader site(s) and leader codon 6. Mutations in the ribosome-binding site for the cat-86 leader, RBS-2, which decreased its strength of binding to 16S rRNA, prevented induction. In contrast, mutations that significantly altered the sequence of RBS-2 but increased its strength of binding to 16S rRNA did not block induction by either chloramphenicol or amicetin. We therefore suspected that the proposed leader site that permitted drug-mediated stalling was located between RBS-2 and leader codon 6. This region of the cat-86 leader contains an eight-nucleotide sequence (conserved region I) that is largely conserved among all known cat leaders. The codon immediately 5' to conserved region I differs, however, between amicetin-inducible and amicetin-noninducible cat genes. In amicetin-inducible cat genes such as cat-86, the codon 5' to conserved region I is a valine codon, GTG. The same codon in amicetin-noninducible cat genes is a lysine codon, either AAA or AAG. When the GTG codon immediately 5' to conserved region I in cat-86 was changed to AAA, amicetin was no longer active in cat-86 induction, but chloramphenicol induction was unaffected by the mutation. The potential role of the GTG codon in amicetin induction is discussed.     

Multiple ribosome binding to the 5'-terminal leader sequence of tobacco mosaic virus RNA. Assembly of an 80S ribosome X mRNA complex at the AUU codon

Tobacco mosaic virus (TMV) RNA with a long 5'-terminal leader sequence, as well as its isolated leader fragment (called omega), can form disome initiation complexes with wheat germ ribosomes. The second ribosome of the disome complex is bound to the leader sequence, upstream of an 80S particle occupying the AUG-containing initiation site [ Filipowicz and Haenni (1979) Proc. Natl Acad. Sci. USA 76, 3111-3115; Konarska et al. (1981) Eur. J. Biochem. 114, 221-227]. In order to identify the parts of omega important for interaction with ribosomes, the 5'-terminally-labelled omega was treated with alkali and the resultant fragments of different lengths were used in binding experiments. A 16-nucleotide-long fragment bearing the AUU sequence at the 3' end is the shortest oligonucleotide capable of forming 80S complexes with wheat germ ribosomes. Full-length (73 nucleotides) omega with AUG at the 3' terminus is the only RNA fragment supporting disome complex formation. Synthetic oligoribonucleotides were prepared for a study of 80S complex assembly at codons other than AUG. Hexadecanucleotide (A) 13A -U-U and, to lesser extent, also (A) 13A -U-C, (A) 13A -U-A and (A) 13A -C-G bind 80S ribosomes. Formation of the (A) 13A -U-U X 80S complex is dependent on the presence of initiator Met- tRNAMerf . Assembly of the 80S particle at the AUU sequence is not an artifact resulting from the terminal position of this triplet. (A) 13A -U-U elongated with over 100 A residues still efficiently binds an 80S ribosome positioned, as established by ribosome protection experiments, at the AUU triplet. The present results support the notion that 80S initiation-like complexes can be formed at sequences containing AUU codons. The possible function of these complexes as intermediates in initiation of translation of some viral RNAs is discussed.     

The initiation region of the SV40 VP1 gene.

The sequence of 15 nucleotides located at the 5' terminus of the plus strand of the SV40 Hind K fragment has been determined as (5') A-G-C-T-T-A-T-G-A-A-G-A-T-G-G (3'). The 3' on OH terminal G of this segment is part of the G-C-C codeword for the N terminal alanine of the VP1 protein. This region therefore presumably corresponds to a ribosome binding site on the 16S late mRNA. Complementarily to the 3' OH of eucaryotic 18S ribosomal RNA and homology with the BMV coat ribosome binding site are discussed.     

Role of a short open reading frame in ribosome shunt on the cauliflower mosaic virus RNA leader

The pregenomic 35 S RNA of cauliflower mosaic virus (CaMV) belongs to the growing number of mRNAs known to have a complex leader sequence. The 612-nucleotide leader contains several short open reading frames (sORFs) and forms an extended hairpin structure. Downstream translation of 35 S RNA is nevertheless possible due to the ribosome shunt mechanism, by which ribosomes are directly transferred from a take-off site near the capped 5' end of the leader to a landing site near its 3' end. There they resume scanning and reach the first long open reading frame. We investigated in detail how the multiple sORFs influence ribosome migration either via shunting or linear scanning along the CaMV leader. The sORFs together constituted a major barrier for the linear ribosome migration, whereas the most 5'-proximal sORF, sORF A, in combination with sORFs B and C, played a positive role in translation downstream of the leader by diverting scanning ribosomes to the shunt route. A simplified, shunt-competent leader was constructed with the most part of the hairpin including all the sORFs except sORF A replaced by a scanning-inhibiting structure. In this leader as well as in the wild type leader, proper translation and termination of sORF A was required for efficient shunt and also for the level of shunt enhancement by a CaMV-encoded translation transactivator. sORF A could be replaced by heterologous sORFs, but a one-codon (start/stop) sORF was not functional. The results implicate that in CaMV, shunt-mediated translation requires reinitiation. The efficiency of the shunt process is influenced by translational properties of the sORF.     

In vitro, the major ribosome binding site on Rous sarcoma virus RNA does not contain the nucleotide sequence coding for the N-terminal amino acids of the gag gene product.

Ribosomes from the reticulocyte lysate bind strongly and mainly to a region located in the 5' end of the Rous sarcoma virus RNA molecule between residues 9 and 53. This binding involves the participation of initiator tRNA and is sensitive to inhibitors of initiation of protein synthesis such as 7-methyl-GMP and aurintricarboxylic acid. The nucleotide sequence of this ribosome binding site has been determined: it conatains a GUG codon centered at position 26 that is not in phase with any termination codon within the 5' end nucleotide sequence of the RNA that we have analyzed (101 residues). However, the predicted N-terminal amino acid sequence starting from this GUG codon (or even from any AUG or GUG codon in the 5' end of the RNA) does not coincide with that of the in vitro-synthesized product of the 5' end proximal gag gene. Nevertheless, inhibition of ribosome binding to this site is accompanied by an inhibition of the in vitro translation of the gag gene.     

mRNAs containing the unstructured 5' leader sequence of alfalfa mosaic virus RNA 4 translate inefficiently in lysates from poliovirus-infected HeLa cells.

Poliovirus infection is accompanied by translational control that precludes translation of 5'-capped mRNAs and facilitates translation of the uncapped poliovirus RNA by an internal initiation mechanism. Previous reports have suggested that the capped alfalfa mosaic virus coat protein mRNA (AIMV CP RNA), which contains an unstructured 5' leader sequence, is unusual in being functionally active in extracts prepared from poliovirus-infected HeLa cells (PI-extracts). To identify the cis-acting nucleotide elements permitting selective AIMV CP expression, we tested capped mRNAs containing structured or unstructured 5' leader sequences in addition to an mRNA containing the poliovirus internal ribosome entry site (IRES). Translations were performed with PI-extracts and extracts prepared from mock-infected HeLa cells (MI-extracts). A number of control criteria demonstrated that the HeLa cells were infected by poliovirus and that the extracts were translationally active. The data strongly indicate that translation of RNAs lacking an internal ribosome entry site, including AIMV CP RNA, was severely compromised in PI-extracts, and we find no evidence that the unstructured AIMV CP RNA 5' leader sequence acts in cis to bypass the poliovirus translational control. Nevertheless, cotranslation assays in the MI-extracts demonstrate that mRNAs containing the unstructured AIMV CP RNA 5' untranslated region have a competitive advantage over those containing the rabbit alpha-globin 5' leader. Previous reports of AIMV CP RNA translation in PI-extracts likely describe inefficient expression that can be explained by residual cap-dependent initiation events, where AIMV CP RNA translation is competitive because of a diminished quantitative requirement for initiation factors.     

Protein-independent folding pathway of the 16S rRNA 5' domain

Evolution of the ribosome from an RNA catalyst suggests that the intrinsic folding pathway of the rRNA dictates the hierarchy of ribosome assembly. To address this possibility, we probed the tertiary folding pathway of the 5' domain of the Escherichia coli 16S rRNA at 20 ms intervals using X-ray-dependent hydroxyl radical footprinting. Comparison with crystallographic structures and footprinting reactions on native 30S ribosomes showed that the RNA formed all of the predicted tertiary interactions in the absence of proteins. In 20 mM MgCl2, many tertiary interactions appeared within 20 ms. By contrast, interactions between H6, H15 and H17 near the spur of the 30S ribosome evolved over several minutes, likely due to mispairing of a central helix junction. The kinetic folding pathway of the RNA corresponded to the expected order of protein binding, suggesting that the RNA folding pathway forms the basis for early steps of ribosome assembly.     

The ribosome binding sites recognized by E. coli ribosomes have regions with signal character in both the leader and protein coding segments.

Oligonucleotide analysis, by a novel computerized procedure, was first applied to determine the sequence of an ideal E. coli promoter (Scherer et al., Nucl. Acids Res. 1978, 5:3759-3773) and has now been used to obtain the sequence of nucleotides that should be present in a messenger RNA for optimum binding to the E. coli ribosome. This sequence is: UU.UUAAAAAUUAAGGAGGUAUAUUAUGAAAAAAAUUAAAAAACUCAA AA U A AUA A CUC G. Comparison of this sequence with each of the 68 ribosome binding site sequences used to generate it shows a preference rather than an absolute requirement for a specific base in any given position. The preference for certain bases persists along the whole length of the RNA within the ribosome binding domain even though nearly half of that length includes translated codons. Thus messages without leader sequences (like lambda CI mRNA) can still have some affinity for the ribosome. Part of the model sequence is complementary to the 3'end of 16S rRNA.     

Erythromycin-induced ribosome stalling and RNase J1-mediated mRNA processing in Bacillus subtilis

Addition of erythromycin (Em) to a Bacillus subtilis strain carrying the ermC gene results in ribosome stalling in the ermC leader peptide coding sequence. Using Δ ermC , a deletion derivative of ermC that specifies the 254 nucleotide Δ ermC mRNA, we showed previously that ribosome stalling is concomitant with processing of Δ ermC mRNA, generating a 209 nucleotide RNA whose 5' end maps to codon 5 of the Δ ermC coding sequence. Here we probed for peptidyl-tRNA to show that ribosome stalling occurs after incorporation of the amino acid specified by codon 9. Thus, cleavage upstream of codon 5 is not an example of 'A-site cleavage' that has been reported for Escherichia coli . Analysis of Δ ermC mRNA processing in endoribonuclease mutant strains showed that this processing is RNase J1-dependent. Δ ermC mRNA processing was inhibited by the presence of stable secondary structure at the 5' end, demonstrating 5'-end dependence, and was shown to be a result of RNase J1 endonuclease activity, rather than 5'-to-3' exonuclease activity. Examination of processing in derivatives of Δ ermC that had codons inserted upstream of the ribosome stalling site revealed that Em-induced ribosome stalling can occur considerably further from the start codon than would be expected based on previous studies.     

Autogenous control: ribosomal protein L10-L12 complex binds to the leader sequence of its mRNA

Ribosomal proteins L10 and L12 are encoded in the L10 operon, situated at position 89.5 min on the Escherichia coli genetic map, and are able to regulate their own translation. The two proteins form a L10-L12 complex that is able to bind specifically to the leader sequence of the L10 operon mRNA and prevent translation. We show that the leader sequence: (i) is required for the translation of mRNA into L10 and L12 proteins; and (ii) contains a unique binding site for the inhibitory L10-L12 complex. We suggest that a specific secondary structure of the leader RNA is required for translation. When this structure is perturbed by L10-L12 binding, by deletion, or point mutations, translation is inhibited. The block on the synthesis of L10 and L12 can presumably be removed by the incorporation of the inhibitory L10-L12 complex into assembling 50S ribosome subunits. We observed that rRNA prevents the binding of L10-L12 to the mRNA. Furthermore, we have identified extended sequence homologies within the 23S rRNA and L10 leader region RNA. The L10-L12 binding site on the mRNA includes part of the homologous sequences.